I've been hacking together a pathtracer in pure Python, just for fun, and since my previous shading-thing wasn't too pretty (Lambert's cosine law), I'm trying to implement recursive pathtracing.
My engine gives an abortive output:
My pathtracing function is defined recursively, like this:
def TracePath2(ray, scene, bounce_count): result = 100000.0 hit = False answer = Color(0.0, 0.0, 0.0) for object in scene.objects: test = object.intersection(ray) if test and test < result: result = test hit = object if not hit: return answer if hit.emittance: return hit.diffuse * hit.emittance if hit.diffuse: direction = RandomDirectionInHemisphere(hit.normal(ray.position(result))) n = Ray(ray.position(result), direction) dp = direction.dot(hit.normal(ray.position(result))) answer += TracePath2(n, scene, bounce_count + 1) * hit.diffuse * dp return answer
And my scene (I made a custom XML description format) is this:
<?xml version="1.0" ?> <scene> <camera name="camera"> <position x="0" y="-5" z="0" /> <direction x="0" y="1" z="0" /> <focalplane width="0.5" height="0.5" offset="1.0" pixeldensity="1600" /> </camera> <objects> <sphere name="sphere1" radius="1.0"> <material emittance="0.9" reflectance="0"> <diffuse r="0.5" g="0.5" b="0.5" /> </material> <position x="1" y="0" z="0" /> </sphere> <sphere name="sphere2" radius="1.0"> <material emittance="0.0" reflectance="0"> <diffuse r="0.8" g="0.5" b="0.5" /> </material> <position x="-1" y="0" z="0" /> </sphere> </objects> </scene>
I'm pretty sure that there's some fundamental flaw in my engine, but I just can't find it...
Here's my new-ish tracing function:
def Trace(ray, scene, n): if n > 10: # Max raydepth of 10. In my scene, the max should be around 4, since there are only a few objects to bounce off, but I agree, there should be a cap. return Color(0.0, 0.0, 0.0) result = 1000000.0 # It's close to infinity... hit = False for object in scene.objects: test = object.intersection(ray) if test and test < result: result = test hit = object if not hit: return Color(0.0, 0.0, 0.0) point = ray.position(result) normal = hit.normal(point) direction = RandomNormalInHemisphere(normal) # I won't post that code, but rest assured, it *does* work. if direction.dot(ray.direction) > 0.0: point = ray.origin + ray.direction * (result + 0.0000001) # We're going inside an object (for use when tracing glass), so move a tad bit inside to prevent floating-point errors. else: point = ray.origin + ray.direction * (result - 0.0000001) # We're bouncing off. Move away from surface a little bit for same reason. newray = Ray(point, direction) return Trace(newray, scene, n + 1) * hit.diffuse + Color(hit.emittance, hit.emittance, hit.emittance) # Haven't implemented colored lights, so it's a shade of gray for now.
I'm pretty sure that the pathtracing code works, as I manually casted some rays and got pretty legitimate results. The problem I'm having (now) is that the camera doesn't shoot rays through all the pixels in the image plane. I made this code to find the ray intersecting a pixel, but it's not working properly:
origin = scene.camera.pos # + 0.5 because it # # puts the ray in the # This calculates the width of one "unit" # *middle* of the pixel # worldX = scene.camera.focalplane.width - (x + 0.5) * (2 * scene.camera.focalplane.width / scene.camera.focalplane.canvasWidth) worldY = scene.camera.pos.y - scene.camera.focalplane.offset # Offset of the imaging plane is know, and it's normal to the camera's direction (directly along the Y-axis in this case). worldZ = scene.camera.focalplane.height - (y + 0.5) * (2 * scene.camera.focalplane.height / scene.camera.focalplane.canvasHeight) ray = Ray(origin, (scene.camera.pos + Point(worldX, worldY, worldZ)).norm())